Voltage converter arrangement for a semiconductor memory

ABSTRACT

In a voltage converter provided in a semiconductor memory and supplying an internal supply voltage to a circuit in the semiconductor memory, a circuit is provided for generating a first voltage whose dependency on an external supply voltage is regulated to a predetermined small value, while another circuit is provided for generating a second voltage whose dependency on the external supplying voltage is larger than the dependency of the first voltage. The voltage converter includes MOS transistors and differential amplifiers interconnected with one another, as well as voltage dividing means. The memory also includes a word line booster for boosting the internal supply voltage.

This is a divisional of application Ser. No. 044,049, filed Apr. 8, 1993, now abandoned, which is a continuation of application Ser. No. 790,065, filed on Nov. 12, 1991, (now U.S. Pat. No. 5,272,393), which is a continuation of application Ser. No. 274,492, filed on Nov. 22, 1988, now abandoned.

BACKGROUND OF THE INVENTION

Field of the Invention

The present invention relates to semiconductor devices, and particularly to voltage converters which generate an internal supply voltage used at least in some of the circuits of the semiconductor devices.

Moreover, it relates to voltage limiters for lowering an external supply voltage in semiconductor integrated circuit chips and impressing the lowered voltage on small geometry transistors in the chips, and particularly to voltage limiters enabling the attainment of stable output voltage in relation to an external supply voltage subject to a wide range of variation.

Description of the Prior Art

In recent years, there has been a problem of the lowering of breakdown voltage accompanying the scaling of semiconductor elements. Although this problem can be solved by lowering supply voltage, this solution is not always preferable for an external interface. Accordingly, it has been proposed to provide a method wherein an internal supply of a lower voltage (e.g. 3 V) than a supply voltage impressed from outside (e.g. 5 V in the case of TTL compatible chips) is prepared in a semiconductor device while the external supply voltage is left unvaried. As to a voltage converter for generating the internal supply from the external supply, a discussion is made, for instance, in Japanese Patent Laid-Open No. 111514/1984 (U.S. application Ser. No. 140,628). The circuit proposed in the aforesaid patent application is shown in FIG. 15(a). This circuit generates an internal supply V_(l) from an external supply V_(CC). Element R denotes a resistance element, and BL₀ and BL₁ denote circuits which are called "unit circuits" in the aforesaid patent application. The "unit circuit" is so designed that a channel between B and C FIG. 15(b)) becomes non-continuous when a voltage between A and C is lower than a prescribed voltage (hereinafter called ON-voltage) while becoming continuous when said voltage is the prescribed voltage or above. FIG. 15(b) is an example of realization of the "unit circuit" described in the aforesaid application.

The characteristics of this circuit are shown in FIG. 15(c). When the external supply voltage V_(CC) is V_(P0) (V_(P0) is the ON-voltage of the unit circuit BL₀) or below, both BL₀ and BL₁ are in the non-continuous state, and therefore an output voltage V_(l) is equal to V_(CC). When V_(CC) exceeds V_(P0), BL₀ turns to be in continuity, and therefore V_(l) is determined by the ratio between the resistance element R and the ON-voltage of BL₀. Accordingly the V_(CC) dependency (inclination m) of V_(l) is smaller than 1 as shown in the figure. When V_(CC) rises and a difference V_(CC) -V_(l) exceeds V_(P1) (V_(P1) is the ON-voltage of the unit circuit BL₁), moreover, BL₁ turns to be in continuity, and the ON-resistance R₁ of BL₁ is connected in parallel to the resistance R. Accordingly, the V_(CC) dependency of V_(l) (inclination m') becomes larger than m.

For the V_(CC) dependency of V_(l), characteristics bent at points P and P' are obtained. Values of V_(CC) at the points P and P' are ##EQU1## The inclinations m and m' are ##EQU2##

The present circuit is advantageous in that it enables the voltage aging of a circuit operated by the internal supply V_(l) (hereinafter abbreviated as an internal circuit), as will be described below. The voltage aging is a technique wherein a voltage higher than the one applied in ordinary operation is impressed on a supply terminal before delivery of semiconductor devices so as to exclude therefrom those devices which become imperfect after the voltage is applied, and it is effective for reducing initial imperfections after the delivery. In order to enable the voltage aging of the internal circuit, it is only required to design V₀ and V₀ ' so that the external supply voltage V_(CC) in ordinary operation be found between V₀ and V₀ ' and that V_(CC) in aging be higher than V₀ '. By such a design as stated above, the operation of the internal circuit is made stable in ordinary operation even when V_(CC) varies, since the V_(CC) dependency m of V_(l) is small therein. On the other hand, V_(l) higher sufficienctly than in ordinary operation is impressed on the internal circuit in aging and thereby the voltage aging of the internal circuit is implemented, since the V_(CC) dependency m' of V_(l) is large in aging.

A problem of the above-described prior art is that the characteristics of internal supply in ordinary operation and the characteristics thereof in aging can not be designed independent of each other. In the circuit of FIG. 15(a), for instance, the characteristics in ordinary operation are determined by BL₀, and those in aging by BL₀ and BL₁. When BL₀ is altered to modify the characteristics in ordinary operation, therefore, the characteristics in aging are also modified simultaneously. The parameters m' and V₀ ' determining the characteristics in aging are expressed as ##EQU3## according to equations (1) to (4). As is apparent from these equations, the parameters m' and V₀ ' determining the characteristics in aging are dependent on m and V₀ which are parameters determining the characteristics in ordinary operation. Accordingly, it is necessary to redesign BL₁ every time when the characteristics in ordinary operation are modified.

FIG. 26 shows a prior-art voltage limiter circuit and an example an application thereof. This example is described in the Extended Abstracts of the 18th Conference on Solid State Devices and Materials, 1896, pp. 307-310.

The operation thereof will be summarized in the following. In the figure, numeral 1 denotes a semiconductor chip of a voltage generator, VC2 a feedback type voltage limiter circuit formed of a differential amplifier, and L1 and L3 circuits comprising small geometry transistors whose breakdown voltage is low. These circuits are the loads of said voltage limiter circuit, for instance. Mark L2 denotes a circuit comprising a transistor whose size is large and whose breakdown voltage is high. Voltages VLO₁ and VLO₂ made lower than an external voltage V_(CC) by the voltage limiter with limiter reference voltages VL1 and VL2 used as references are impressed on L1 and L3, respectively. Meanwhile, V_(CC) is impressed directly on L2. Marks φ₁, φ₂ and φ₃ denote driving signals for L1, L2 and L3 respectively. φ₁ ' and φ₃ ' are signals controlling a current of the differential amplifier in the voltage limiter VC2 and turning a transistor Q₈ ON and OFF. These signals are varied from High level (V_(CC)) to Low level (V_(SS)) at a time point when L1 and L3 start operations in response to φ₁ and φ₃ '. Thereby the transistor Q₈ in VC2 is turned. ON and the current of the differential amplifier is increased, so that it can respond at high speed to fluctuations of VLO₁ and VLO₂ due to current fluctuations of L1 and L3. When L1 and L3 do not operate, on the other hand, said signals are made to be at High level and thereby Q₈ is cut off. Thereby the current flowing through the differential amplifier turns to have a value obtained only by Q₉. By setting g_(m) of Q₈ to be large and g_(m) of Q₉ to be small, accordingly, a voltage limiter operating at high speed and consuming low power can be realized.

Besides, VC2 comprises two circuits connected to separate loads respectively in the figure, and 10 this is to prevent the fluctuation of an internal supply voltage due to the current fluctuation of one load from affecting the other load.

According to the above-described prior art, the differential amplifier employed in the voltage limiter circuit is so constructed, as shown in FIG. 26, that the P-channel transistors Q₈ and Q₉ are used as common source loads, N-channel transistors Q₁₂ and Q₁₃ as active loads and P-channel transistors Q₁₀ and Q₁₁ as a source-coupled pair and a reference voltage and a limiter output voltage are inputted directly to the gates thereof. In such a construction as described above, however, a gate-source voltage V_(GS) of the source-coupled pair depends on a difference voltage between V_(CC) and VL or VLO, since Q₈ and Q₉ make the same operations as resistances in a non-saturation region. When the difference between V_(CC) and VL becomes small, in other words, when V_(CC) turns low or VL turns high, therefore, V_(GS) becomes small and a current lessens, which results in the slowdown of a response speed. In the condition of V_(CC) ≦VL+V_(T), besides, there occurs a problem that Q₁₀ and Q₁₁ are cut off (discontinue operating as the amplifier). V_(T) is an absolute value of the threshold voltage of the transistors Q₁₀ and Q₁₁.

When VL=3(V) and V_(T) =1(V) are substituted as general numerical values in the above expression, then V_(CC) ≦4(V), and so the circuit does not operate if V_(CC) is a voltage of 4(V) or below. In order to secure operations against the drop of a supply voltage due to a spike current or the like, DRAM for products or the like needs to be so designed as to operate with a voltage as low as V_(CC) =3 V approximately. DRAM or the like according to a prior-art system does not operate below V_(CC) =4 V, in this relation, and therefore the present circuit is not suitable for practical use.

In addition, the current of the differential amplifier is controlled only at two stages, stages of standby and operation, in the prior art. Moreover, the signal used therefor is not generated on the basis of direct detection of the state of a load, but generated in response to a load driving signal or a clock signal given before or behind said signal. Therefore the current of the differential amplifier needs to be kept large for a longer time than a time required for completion of the operation of the load. Consequently, power consumption is not reduced sufficiently.

SUMMARY OF THE INVENTION

A first object of the present invention is to solve the above-stated problems and to make it possible to design the characteristics of an internal supply in ordinary operation and the characteristics thereof in aging, independent of each other.

A second object of the present invention is to furnish a voltage limiter which operates at high speed even when a supply voltage is equal to an output voltage thereof and further which consumes low power.

In a voltage converter provided in a semiconductor device and supplying an internal supply voltage to at least some circuits of said semiconductor device, the aforesaid first object is attained by providing a circuit which generates a first voltage whose dependency on an external supply voltage is small, a circuit which generates a second voltage whose dependency on the external supply voltage is larger than the first voltage and a selector selecting said first or second voltage. Furthermore, in a semiconductor integrated circuit incorporating therein a voltage limiter provided with a circuit which generates a voltage made lower than the one of an external power supply, a differential amplifier circuit which receives as one input an output of this voltage lowering circuit and amplifies a difference voltage between said input and the other input and a voltage lowering circuit which outputs an internal voltage under the control of an output of said differential amplifier circuit and feeds back this internal supply voltage as the other input to the aforesaid differential amplifier circuit, the aforesaid second object is attained by providing the differential amplifier circuit with an active load of P-channel transistors and with a source-coupled pair of N-channel transistors, or by adding a circuit shifting the level of an input voltage of the voltage limiter in the above-mentioned integrated circuit to said limiter.

The foregoing and other objects, advantages, manner of operation and novel features of the present invention will be understood from the following detailed description when read in connection with the accompanying drawings.

When the semiconductor device is in the state of ordinary operation, an output of a voltage generator used exclusively for ordinary operation serves as an internal supply voltage, according to the above-stated construction. When the device is in the state of testing or aging, an output of a separate voltage generator from the one used in ordinary operation serves as the internal supply voltage, according also to the above construction. By preparing the exclusive voltage generator for each state of operation in this way, each voltage generator can be designed independent of the other. This enables the removal of a disadvantage that the characteristics in ordinary operation affect those in aging, which is the problem in the previously-described prior art, for instance.

The problem of the reduction of power consumption of the aforesaid voltage limiter is solved by providing two or more current controlling transistors for the differential amplifier and further by providing a circuit detecting the amount of lowering of an output voltage of the voltage limiter and controlling the aforesaid current controlling transistors on the basis of the detection.

Moreover, by inserting a level shift circuit in an input terminal of the differential amplifier so as to lower a voltage impressed on the input terminal of the differential amplifier, by the amount of V_(T) of the transistors of the source-coupled pair or by the amount of a voltage lower than V_(T), a gate-source voltage V_(GS) of the transistors of the source-coupled pair is secured to be V_(T) or above even when a supply voltage and the output voltage of the limiter turn equal to each other.

Furthermore, by using N-channel transistors for the source-coupled pair transistors of the differential amplifier, the effect of V_(CC) is removed, since V_(GS) of the source-coupled pair transistors turns to be determined on the basis of V_(SS) as a reference. Accordingly, operations can always be conducted irrespective of a value of V_(CC) on condition that a reference voltage VL is V_(T) or above.

By using the two methods described above, the voltage limiter can operate even when the supply voltage and the output voltage are equal to each other, since V_(GS) of the source-coupled pair transistors thereof is secured to be V_(T) or above.

By providing two or more current controlling transistors of the differential amplifier, besides, a current value can be controlled more finely, and therefore a wasteful current can be reduced, thus the attainment of power reduction being enabled. Moreover, by providing the circuit detecting the amount of lowering of the output voltage of the voltage limiter and generating a current control signal automatically in accordance with this amount, a current can be made large only for a period when the current flows actually to a load, and therefore a wasteful current can be eliminated. By combining the two means, in addition, fine control can be conducted momentarily for a change in the current of the load, and therefore a further power reduction can be attained.

The foregoing and other objects, advantages, manner of operation and novel features of the present invention will be understood from the following detailed description when read in connection with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1a to 3b are structural views of voltage converters being embodiments of the present invention and graphs showing the characteristics thereof; FIGS. 4a to 9 are circuit diagrams of element circuits in the voltage converters of FIGS. 1a to 3b ; FIG. 10 is a structural view of DRAM to which the present invention is applied; FIG. 11 is an operating waveform diagram of DRAM of FIG. 10; FIGS. 12a, 12b and 13 are circuit diagrams of element circuits of DRAM of FIG. 10; FIGS. 14a-14b are graphs showing the characteristics of the voltage converter in FIG. 10; and FIGS. 15a-15c are circuit diagrams of a prior-art voltage converter and a graph showing the characteristics thereof. FIGS. 16 to 18 and FIGS. 20 to 24 are illustrations of embodiments of the present invention; FIG. 19 is an operating waveform diagram of the embodiment of FIG. 18; FIG. 25 is an operating waveform diagram of FIGS. 21 and 22; and FIG. 26 is an illustration of a prior-art example.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Embodiments of the present invention will be described hereunder with reference to the drawings. Although the following description will be made on the case wherein the external supply voltage V_(CC) is positive, the present invention can be applied also to the case wherein V_(CC) is negative, by reversing the polarity and others of transistors.

FIG. 1(a) is a structural view of a voltage converter which is a first embodiment of the present invention. In the figure, numerals 1 and 2 denote voltage generators, and 3 a selector. One of outputs V₁ and V₂ of the two voltage generators 1 and 2 is selected to be an output voltage V_(l) by the selector 3. Out of the outputs of the two voltage generators, V₁ has small dependency on the external supply voltage V_(CC), in other words, it is stable in relation to V_(CC). In contrast, V₂ has relatively large dependency on V_(CC). The selector 3 is controlled by a signal TE showing whether the semiconductor device is in the state of ordinary operation or in the state of testing. V₁ is selected to be V_(l) when the device is in the state of ordinary operation, while V₂ is selected to be same when the device is in the state of testing.

The characteristic features of this circuit lie in that the dependency of the operation of an internal circuit on the internal supply voltage can be tested and that the voltage aging of the internal circuit can be executed. FIG. 1(b) shows one example of the V_(CC) dependency of the voltage of each element of this circuit. This is an example wherein the external supply voltage V_(CC) =5±0.5 V (denoted by a in the figure) and the internal supply voltage V_(l) =3 V in ordinary operation and wherein the external supply voltage V_(CC) =8 V (denoted by b in the figure) and the internal supply voltage V_(l) =4.8 V in aging. V₁ has small V_(CC) dependency and is almost fixed substantially (it is 3 V herein, provided that V₁ =V_(CC) when V_(CC) <3 V). On the other side, V₂ rises monotonously in accordance with V_(CC) (V₂ =0.6 V_(CC) herein). Since V_(l) =V₁ in ordinary operation, the stabilized internal supply voltage (=3 V) is impressed on the internal circuit, and thereby the operation of the internal circuit is stabilized. Since V_(l) =V₂ in the state of testing, on the other side, the internal supply voltage to be impressed on the internal circuit can be varied by varying V_(CC). While it is difficult to test the dependency of the operation of the internal circuit on the supply voltage in the prior-art voltage converter, since the stabilized voltage is always impressed on the internal circuit therein, the test becomes possible according to the present circuit, and in addition, a design with a margin for fluctuations of the internal supply voltage can be made, since the internal supply voltage in ordinary operation is stabilized. In order to conduct the voltage aging of the internal circuit according to the present circuit, it is only required to turn V_(CC) to be an aging voltage (8 V in this example) in the state of testing. The device being in the state of testing, V_(l) =V₂ (=4.8 V), and therefore a higher internal supply voltage than in ordinary operation is impressed on the internal circuit.

As is apparent from the above description, the voltage generator 1 for ordinary operation needs to meet only the characteristics in the state of ordinary operation, while the voltage generator 2 for testing needs to meet only the characteristics in the state of testing. In other words, the generators 1 and 2 can be designed independent of each other.

In the present embodiment, outputs of two voltage generators are selected to be the internal supply voltage. A design may also be adopted, in this connection, wherein outputs of three or more voltage generators are selected. This is effective in the case when the internal circuit is tested in a plurality of conditions, for instance.

FIG. 2(a) is a structural view of a voltage converter which is a second embodiment of the present invention. This embodiment differs from the embodiment of FIG. 1 in that a selector 3 is controlled by an output of a comparator 4. The comparator 4 compares the output V₁ of the voltage generator for ordinary operation with the output V₂ of the voltage generator for aging and controls the selector 3 so that the higher voltage be selected.

The characteristic feature of this circuit lies in that an internal supply having the characteristics enabling the voltage aging of the internal circuit can be obtained without applying such a control signal as TE of FIG. 1. FIG. 2(b) shows one example of the V_(CC) dependency of the voltage of each element of this circuit. This example shows the cases when the external supply voltage V_(CC) =5±0.5 V in ordinary operation and V_(CC) =8 V in aging and when the internal supply voltage V_(l) =3 V in ordinary operation and V_(l) =4 V in aging. V₁ is a stabilized voltage like the one in the case of FIG. 1. On the other side, V₂ rises monotonously in accordance with V_(CC) (V₂ =V_(CC) /2 herein). Accordingly, V₁ >V₂ when V_(CC) <6 V, and V₁ <V₂ when V_(CC) >6 V. Since V_(l) equals the higher of V₁ and V₂, V_(l) =3 V when V_(CC) <6 V, while V_(l) =V_(CC) /2 when V_(CC) >6 V. In other words, the characteristics bent at a point whereat V_(CC) is some voltage (6 V in this case) between an ordinary operation voltage and an aging voltage, are obtained. When V_(CC) is within the sphere of the ordinary operation voltage (5±0.5 V herein, denoted by a in the figure), V_(l) is stabilized, and therefore the operation of the internal circuit becomes stable. When V_(CC) is within the aging voltage (8 V herein, denoted by b in the figure), V_(l) becomes higher (4 V herein) than in ordinary operation. Therefore a higher voltage than in ordinary operation is impressed on the internal voltage, so that the voltage aging of the internal circuit be conducted.

As is apparent from the above description, the voltage generator 1 for ordinary operation needs to meet only the characteristics shown when V_(CC) is within the sphere of the ordinary operation voltage, while the voltage generator 2 for aging needs to meet only the characteristics shown when V_(CC) is within the aging voltage. In other words, the generators 1 and can be designed independent of each other. The problem in the previously-described prior art that the characteristics in ordinary operation affect those in aging is thus removed. Therefore, a circuit design is easier than according to the prior art.

FIG. 3(a) is a structural view of a voltage converter which is a third embodiment of the present invention. This circuit differs from the circuit of FIG. 2 in that a plurality of output terminals (V_(la), V_(lb), V_(lc)) are provided. Moreover, the voltage generator for aging, the selector and the comparator are provided in a plurality respectively. Voltage generators 2A, 2B and 2C for aging generate voltages V_(2a), V_(2b) and V_(2c) respectively. Selectors 3A, 3B and 3C generate V_(la), V_(lb) and V_(lc) respectively from the voltage V₁ for ordinary operation and the voltages V_(2a), V_(2b) and V_(2c) for aging. On the occasion, the voltage for ordinary operation is compared with the voltages for aging by comparators 4A, 4B and 4C respectively, and the higher voltages are selected to be V_(la), V_(lb) and V_(lc) in the same way as in the case of FIG. 2.

The characteristic feature of this circuit lies in that the voltage aging can be executed in different conditions according to circuits. One example of the V_(CC) dependency of an output voltage is shown in FIG. 3(b). When V_(CC) is within the sphere of the ordinary operation voltage (denoted by a in the figure), V₁ is higher than V_(2a), V_(2b) and V_(2c), and therefore any one of V_(la), V_(lb) and V_(lc) is equal to V₁. When V_(CC) is within the aging voltage (denoted by b in the figure), V_(2a), V_(2b) and V_(2c) are higher than V₁, and therefore V_(la), V_(lb) and V_(lc) are equal to V_(2a), V_(2b) and V_(2c) respectively. In other words, V_(la), V_(lb) and V_(lc) are stabilized to be the same voltage in ordinary operation, while they turn to be different voltages from one another in aging. Accordingly, internal circuits whereon V_(la), V_(lb) and V_(lc) are impressed respectively are subjected to aging in different conditions from one another.

As described above, another characteristic feature of the present invention lies in that it enables the preparation of the circuit which makes it possible to execute aging in different conditions for each circuit. If it is intended to prepare the same circuit by the previously-described prior art, it would be needed to prepare a plurality of circuits of FIG. 15(a), for instance. If there is non-uniformity in elements among these circuits in a plurality, however, it would be difficult to make uniform voltage values in ordinary operation and the V_(CC) dependency thereof. In the circuit of FIG. 3(a), in contrast, a plurality of internal supplies are prepared on the basis of one stabilized voltage V₁ in ordinary operation, and therefore it is easy to make their voltage values uniform.

Next, a detailed description will be made on individual circuits constituting the voltage converters in FIGS. 1 to 3 respectively.

First, the voltage generator 1 for ordinary operation will be described. A well-known stabilized-voltage generator, e.g. a circuit using a breakdown voltage of a Zener diode or a base-emitter voltage of a bipolar transistor as a reference voltage, can be employed as the voltage generator 1 for ordinary operation. One example of such a circuit is shown in FIG. 4(a). In the figure, numeral 10 denotes an NPN transistor, 11 a Zener diode, 12 and 13 resistors. A voltage between an output V₁ and a node 14 and a voltage between the node 14 and the earth are a breakdown voltage V₂ of 11 and a base-emitter voltage V_(be) of 10 respectively, and either of-them is fixed substantially irrelevant to the supply voltage V_(CC). Accordingly, an output voltage of this circuit is V₁ =V₂ +V_(be), i.e. fixed. If such a band-gap reference as shown in FIG. 4(b) is used, a voltage being stable for a change in temperature as well as for a change in V_(CC) can be obtained. Besides, a circuit proposed in Japanese Patent Application No. 123797/1987, for instance, may be employed as well.

Next, the voltage generator 2 will be described. The output V₂ of the voltage generator 2 is used in testing or aging of a semiconductor device, and therefore the characteristics thereof are to be determined in accordance with the conditions of testing or those of aging. The voltage generator 2 for aging employed in the embodiment of FIG. 2, for instance, is a circuit which generates a voltage of 1/2 of the supply voltage V_(CC). This can be realized by a circuit as shown in FIG. 5(a), for instance. In the figure, numerals 30 and 32 denote n-channel MOS transistors, 31 and 33 p-channel MOS transistors, and 34 and 35 resistors. On-resistance of the MOS transistors is smaller sufficiently than R₃₄ and R₃₅ (R₃₄ and R₃₅ are resistance values of 34 and 35 respectively), and if R₃₄ =R₃₅, a voltage of a node 36 is 1/2 of the supply voltage V_(CC), i.e. V_(CC) /2. Accordingly, voltages of nodes 37 and 38 are V_(CC) /2+V_(tn) and V_(CC) /2-|V_(tp) | respectively (V_(tn) and V_(tp) are threshold voltages of the n-channel MOS transistor and the p-channel MOS transistor respectively), and the output voltage is V₂ =V_(CC) /2. By changing the ratio between R₃₄ and R₃₅, besides, it is made possible to generate a voltage being multiple of V_(CC) (e.g. 0.6 V_(CC) as in the voltage generator for testing of FIG. 1).

The characteristic features of this circuit lie in that a consumed current is determined by R₃₄ and R₃₅ and that current drivability is determined by the MOS transistors 32 and 33 in an output stage. By setting R₃₄, R₃₅ and the channel widths of 32, 33 large enough, accordingly, a circuit consuming small current and having large current drivability can be prepared. In the case when the current drivability does not need to be large (e.g. when a circuit of FIG. 8 is employed as the selector 3 and the comparator 4 as will be described later), a circuit of FIG. 5(b) or (c) may be employed. The circuit of FIG. 5(b) is formed simply by dividing V_(CC) by resistors R₃₄ and R₃₅. A modified version of FIG. 5(b), could be formed using a plurality of diode-connected MOS transistors 36 to 38 are used instead of resistors. This circuit is advantageous in that it occupies a smaller area than that formed by using the resistors. In the case when the division ratio of V_(CC) is a simple integer ratio, all the MOS transistors are formed in the same circuit configuration to avoid a back-bias effect, and thereby a circuit that is hardly affected by the non-uniformity in manufacture can be prepared. For example, a p-channel MOS transistor in an n-well is used and each n-well is connected to the source of each MOS transistor which is diode-connected, so as to avoid the back-bias effect.

Another method for realizing the voltage generator 2 is shown in FIG. 5(c). This circuit generates a voltage obtained by application of an offset voltage being multiple of the external supply voltage V_(CC) (V₂ =3 V_(CC) /4-1.5 (V) herein). In the figure, numerals 40 to 42 denote diodes, and the three diodes are connected in series so that a voltage of a node 43 is lower by about 2 V than the supply voltage V_(CC). When the resistance ratio is set to be R₃₄ : R₃₅ =1:3, an output voltage of V₂ =3/4 (V_(CC) -2)=3 V_(CC) /4-1.5 (V) can be obtained.

Next, a description will be made on a method for realizing the selector 3 and the comparator 4 employed for the embodiments of FIGS. 2 and 3. One method for realizing the selector 3 and the comparator 4 is shown in FIG. 6. In the figure, numerals 50 and 51 denote differential amplifiers, 52 and 53 NAND gates, 54 and 55 inverters, 56 and 57 p-channel MOS transistors, and 58 and 59 n-channel MOS transistors. In this circuit, the higher in voltage of inputs V₁ and V₂ is connected to an output V_(l) through MOS transistors 56, 58 or 57, 59. When V₁ is higher than V₂, outputs of the differential amplifiers 50 and 51 turn to be of high potential and low potential respectively, while outputs of the NAND gates 52 and 53 turn to be of low potential and high potential respectively. Therefore the p-channel MOS transistor 56 becomes continuous, while 57 becomes non-continuous. Moreover, outputs of the inverters 54 and 55 turn to be of high potential and low potential respectively, and therefore the n-channel MOS transistor 58 becomes continuous and 59 non-continuous. Accordingly, the input V₁ and the output V_(l) are connected through the MOS transistors 56 and 58. When V₂ is higher than V₁, to the contrary, the amplitude of the potential is reverse to the above, and the input V₂ and the output V_(l) are connected through the MOS transistors 57 and 59.

The characteristic feature of the present circuit lies in that the input V₁ turns to be the output V_(l) as it is when V₁ >V₂. By designing the circuit so that the ON-resistance of MOS transistors 56 and 58 be small enough, accordingly, the voltage stability Of the output V_(l) can be made to have the same value as that of the output V₁ of the voltage generator 1 for ordinary operation.

Another method for realizing the selector 3 and the comparator 4 is shown in FIG. 7. In the figure, numerals 60 and 61 denote differential amplifiers, 62 and 63 p-channel MOS transistors, and 64 a current source. The present circuit is composed of a voltage amplifier formed of 60 and 62 and of a voltage amplifier formed of 61 and 63, and the transistors 62 and 63 in the respective output stages of the two amplifiers are connected in parallel. The current source 64 is provided to give a bias current to the output stages. When V₁ >V_(l), an output of the differential amplifier 60 turns to be of low potential, and therefore the p-channel MOS transistor 62 is put in the state of continuity. When V₁ <V_(l), on the other hand, the output of the differential amplifier 60 turns to be of high potential, and therefore 62 becomes non-continuous. At the same time, the MOS transistor 63 is continuous when V₂ >V_(l), and noncontinuous when V₂ <V_(l). When the output voltage V_(l) is lower than one of V₁ and V₂ at least, accordingly, at least one of MOS transistors 62 and 63 is in the state of continuity, and therefore a current flows from the supply V_(CC) to V_(l), so as to make the potential of V_(l) rise. This rise of potential continues until both of the MOS transistors 43 and 44 turn to be in the state of non-continuity with V_(l) becoming equal to the potential of the higher of V₁ and V₂. After all, V_(l) turns stable in a state wherein it is equal to the potential of the higher of V₁ and V₂.

The present circuit is characterized in that the circuit itself has a function of amplification. Even when the current drivability of the voltage generators 1, 2, 2A, 2B and 2C of FIGS. 2 and 3 is small, therefore, the current drivability of V_(l) can be made large. Accordingly, not the circuit of FIG. 5(a), but the simple circuit of FIG. 5(b) or (c) can be employed, for instance, as the voltage generator 2.

While the output voltage V_(l) is equal to the input voltage V₁ or V₂ in the above example, it can also be made multiple of V₁ or V₂. FIG. 8 shows one method for realizing a circuit making this available. This circuit differs from the circuit of FIG. 7 in that the differential amplifiers 60 and 61 do not receive V_(l) itself as an input, but receive a voltage R₆₆ V_(l) /(R₆₅ +R₆₆) which is obtained by dividing V_(l) by resistances 65 and 66 (R₆₅ and R₆₆ are resistance values of 65 and 66 respectively). Therefore the voltage R₆₆ V_(l) /(R₆₅ +R₆₆) is equal to the higher of the voltages V₁ and V₂. In other words, the output voltage V_(l) is (R₆₅ +R₆₆)/R₆₆ times as high as the higher of the voltages V₁ and V₂.

This circuit is advantageous in that a voltage being arbitrary multiple of an input voltage can be obtained by changing the ratio between the resistances R₆₅ and R₆₆. This advantage is effective particularly for the case when only a specified voltage is obtained as the stabilized voltage V₁. In the case when the previously-mentioned band-gap reference is used as the voltage generator 1, for instance, the output voltage thereof is V₁ =1.26 V. In order to obtain therefrom the output voltage V_(l) =3 V, for instance, it is only required to set the ratio to be R₆₅ :R₆₆ =1.74:1.26.

Besides, the differential amplifiers employed in the circuits of FIGS. 6 to 8 can be realized, for instance, by a circuit of FIG. 9. In the figure, numeral 70 denotes the main body of the differential amplifier, which consists of p-channel MOS transistors 71, and n-channel MOS transistors 72, 73, 74, 75. When the voltage of an input V_(in1) is higher than that of V_(in2), an output V_(out) turns to be of high potential, and when the voltage of V_(in2) is higher than that of V_(in1), V_(out) turns to be of low potential. Numeral 80 denotes a circuit for making the MOS transistor 75 operate as a current source. 81 denotes a p-channel MOS transistor operating as a high resistance, and it determines a current flowing to an n-channel MOS transistor 82. 75 and 82 form a current mirror circuit, and therefore a current being multiple of the current flowing to 82 (the ratio in conductance between 75 and 82) flows to 74. In the case when a plurality of differential amplifiers are employed as in FIGS. 6 to 8, the area occupied thereby can be saved by providing the circuit 80 only in one and by connecting commonly the gates of the transistors 75 of the differential amplifiers in a plurality.

Next, a description will be made on an example wherein the present invention is applied to DRAM (dynamic random access memory). FIG. 10 is a structural view of DRAM to which the present invention is applied, and FIG. 11 is an operation waveform diagram thereof. In the figure, numeral 100 denotes a voltage converter according to the present invention, 200 a memory array, 201 a word driver, 202 a word-line booster, 203 a data-line precharge circuit, 204 a sense amplifier, 205 a sense amplifier drive signal generator, 206 a data-line selector, 207 a row decoder, 208 a row address buffer, 209 a column decoder, 210 a column address buffer, 211 a main amplifier, 202 a D_(out) buffer, 213 a write circuit, 214 a D_(in) buffer, and 215 a timing generator. In this memory, small geometry MOS transistors are employed for the memory array 200 which has a large effect on integrity, and they are operated by an internal supply V_(l) (e.g. 3.3 V) lower than an external supply V_(CC) (e.g. 5 V). On the other side, the circuits 207 to 215 having not so large an effect on the integrity are operated directly by the external supply V_(CC). In order to operate the memory array by V_(l), internal supplies V_(x), V_(p), V_(d) and V_(y) are supplied from the voltage converter 100 to the word-line booster 202, the data-line precharge circuit 203, the sense amplifier drive signal generator 205 and the data-line selector 206, respectively.

In the voltage converter 100, a circuit 101 generating V_(l) is constructed in the same way as in FIG. 2(a). Concretely, the higher of the voltages of the voltage generator 1 for ordinary operation and the voltage generator 2 for aging is selected to be V_(l) by the selector 3. Buffers 5 to 8 are provided for making load drivability large. The buffers 5, 7 and 8 are circuits generating the voltages V_(x), V_(d) and V_(y) equaling V_(l) respectively. The buffer 6 is a circuit generating the voltage V_(p) which is 1/2 of V_(l). As for the buffers 5, 7 and 8, a circuit proposed in Japanese Patent Application No. 294115/1987, for instance, can be used therefor. The buffer 6 can be realized, for instance, by a circuit of FIG. 12(a). This circuit generates a voltage of 1/2 of a supply voltage (V_(l) herein), like the circuit of FIG. 5(a). In the present circuit, however, an MOS transistor 32 in an output stage alone is connected not to V_(l) but to V_(CC). This is because V_(CC) having larger current drivability is preferable for the output stage which is required to drive a load directly, although the connection may be made to V_(l), of course.

In the memory array 200, so-called 1-transistor 1-capacitor type dynamic memory cells MC_(ij) each consisting of an MOS transistor 220 and a capacitor 221 are disposed at the intersecting points of word lines W_(i) and data lines D_(j). Although only two word lines (W_(i), W_(i+1)) and only a pair of data lines (D_(j), D_(j)) are shown in the figure, these lines are disposed in large numbers, in practice, longitudinally and laterally. Besides, one end 222 (plate) of the capacitor 221 is connected to a direct-current source. Although the voltage value thereof may be set arbitrarily, it is preferable to connect the cells to V_(p) (=V_(l) /2) in view of the breakdown voltage of the capacitor 221.

The word driver 201 is a circuit which receives an output of the row decoder 207 and supplies a word-line drive signal φ_(x) to a selected word line through an MOS transistor 223. The signal φ_(x) is prepared by the word-line booster 202. This circuit 202 boosts φ_(x) to be higher than a supply voltage. The power source of this circuit is not the external supply V_(CC), but the internal supply V_(x) prepared by the voltage converter. Accordingly, φ_(x) is boosted with V_(x) as a reference, not with V_(CC). In other words, the voltage of φ_(x) is (1+α) times (0<∝<1) as high as V_(x) as shown in FIG. 11.

One method for realizing the word-line booster 202 is shown in FIG. 13. This is a circuit which generates the signal φ_(x) a prescribed time after an input signal φ_(in) turns to be of high potential. The main part of this circuit consists of inverters 250 to 253,260 to 263, a capacitor 270 for boosting, and a precharge circuit 280. Trains of the inverters 250 to 252 and 260 to 262 form a circuit for obtaining a prescribed delay time. While V_(CC) is used as a power source for these inverters, V_(x) may also be used therefor. Outputs of 252 and 262 are varied from high potential to low respectively a prescribed time after φ_(in) turns to be of high potential. An output of 253 rises, consequently. Since the power source of this inverter 253 is V_(x), the voltage of a node 271 is varied from 0 V to V_(x). With the potential of one end 271 of the capacitor 270 rising, the potential of the other end 272 of the capacitor rises due to capacity coupling. The voltage of the node 272 is set beforehand to be V_(x) -V_(t) (V_(tn) is the threshold voltage of an n-channel MOS transistor) by the precharge circuit 280 (a precharge signal φ_(p) is of high potential when the memory is in a standby state), and therefore it rises to ##EQU4## due to the capacity coupling. In the above expression, C_(b) and C_(p) denote the capacity of the capacitor 270 and the parasitic capacitance of the node 272 respectively. Since the inverter 263 (consisting of a p-channel MOS transistor 264 and n-channel MOS transistors 265 and 66) operates with this voltage as a supply, the potential of the output φ_(x) rises also to said voltage. MOS transistor 265 of the inverter 263 is provided so as to prevent the impression of an excessive voltage on 266. Since the gate of 265 is connected to V_(CC) (it may also connected to V_(x)), the drain voltage of 266 does not exceed V_(CC) -V_(tn). A circuit 290 is provided to prevent the excessive rise in the potential of φ_(x). The potential of φ_(x) does not exceed V_(CC) +2 V_(tn), since n-channel MOS transistors 291 and 292 in diode connection are connected in series. The source of this MOS transistor 292 may be connected also to V_(x). A circuit 300 is provided for preventing the lowering of the potential of φ_(x) due to a leak current or the like when φ_(x) is boosted for a long period. Mark φ₁ denotes a signal being of high potential while the memory is in an active state, and φ₂ is a signal turning to be of high potential periodically. When φ₂ turns to be of high potential, the potential of a node 305 is boosted to be higher than V_(x) due to the capacity coupling by a capacitor 304, and the lowering of the potential of φ_(x) is thereby complemented.

The data-line precharge circuit 203 is provided for setting each data line at a prescribed voltage (the internal supply voltage V_(p) herein) prior to reading of memory cells. By the impression of a precharge signal φ_(p), MOS transistors 224 to 226 are put in the state of continuity, and the voltage of data lines D_(j), D_(j) becomes equal to V_(p). On the occasion, besides, sense amplifier drive signals SAN and SAP, on which a description will be made later, are set at V_(p) simultaneously by MOS transistors 233 to 235.

When φ_(x) is impressed on the word line, a signal charge is read out of each memory cell to each data line, and the potential of the word line changes. The operation waveform diagram of FIG. 11 shows the case when a high potential (≈V_(d)) is accumulated beforehand in the capacitor of the memory cell. The potential of the data line D_(j) rises slightly, so as to cause a potential difference from Dj. The sense amplifier 203 is a circuit for amplifying this minute signal, and it is constructed of a flip-flop of n-channel MOS transistors 227,228 and a flip-flop of p-channel MOS transistors 229,230. The sense amplifier is activated by turning φ_(sa) to be of high potential and φ_(sa) to be of low potential and thereby putting MOS transistors in the state of continuity. SAN is earthed through 231, while SAP is connected to the internal supply V_(d) through 232. In this way, the minute potential difference between the data lines D_(j) and D_(j) is amplified, and one (D_(j) in the case of FIG. 11) turns to be at V_(d), while the other (D_(j) in the case of FIG. 11) turns to be at 0 V.

The data-line selector 206 is a circuit which receives an output of the column decoder 209 and connects a selected data-line couple to input/output lines I/O, I/O through MOS transistors 236,237. In the case of reading, data latched in the sense amplifier are outputted to a data output terminal D_(out) through an input/output line, the main amplifier 11 and the D_(out) buffer 212. In the case of writing, data inputted from a data input terminal D_(in) are set on the input/output lines I/O, I/O through the D_(in) buffer 214 and the write circuit 213 and further are written in the memory cells through the MOS transistors 236, 237 and the data lines D_(j), D_(j). Numeral 238 denotes a circuit provided for limiting to V_(y) the voltage of a signal Y_(j) ' to be impressed on the gates of the MOS transistors 236 and 237, and it can be realized, for instance, by connecting two stages (240,241) of an inverter and using V_(y) for the supply of the second stage, as shown in FIG. 12(b). In other words, the voltage amplitude of the signal Y_(j) ' is made to be V_(y), while the voltage amplitude of an output Y_(j) of the column decoder is V_(CC). This circuit is provided by the following reason. The amplitude of the input/output line in writing is V_(CC), since the write circuit 213 operates with V_(CC). If the voltage of Y_(j) ' were not limited beforehand, accordingly, a voltage V_(CC) -V_(tn) (V_(tn) is the threshold voltage of MOS transistors 236, 237) would be applied on the memory array. By the way, the voltage of Y_(j) ' may be V_(CC), if the write circuit 213 is made to operate with V_(l). The circuit 238 is not needed in this case.

The row address buffer 208 and the column address buffer 210 are circuits which receive an address signal A_(n) inputted from outside and generate a row address signal a_(rn) and a column address signal a_(cn) respectively. These address signals are used for selection of word lines and data lines by the row decoder 207 and the column decoder 209. The timing generator 215 is a circuit which generates internal timing signals necessary for the operation of the memory from control signals (a row address strobe signal RAS, a column address strobe signal CAS and a write enable signal WE) inputted from outside. As described previously, these circuits are operated directly by the external supply V_(CC). This is because these circuits do not affect the integrity very much and therefore do not need the employment of small geometry MOS transistors therefor and because the use of the external supply is advantageous for an interface receiving external signals. However, they may also be designed to operate with V_(l), of course.

The V_(CC) dependency of the voltage of each part is shown in FIG. 14(a) and (b). The figure exemplifies the case when an external supply voltage in ordinary operation is V_(CC) =5±0.5 V, one in aging is V_(CC) =8 V, an internal supply voltage in ordinary operation is V_(l) =3.3 V, and one in aging is V_(l) =4 V. When V_(CC) is some voltage (6.6 V in this case) between an ordinary operation voltage and an aging voltage, the characteristics bent at said voltage are obtained in the same way as in the case of FIG. 2. Since V_(x), V_(d) and V_(y) are equal to V_(l), they are 3.3 V in ordinary operation and 4 V in aging. The voltage of the word-line drive signal φ_(x) is equal to (1+α) V_(x) as stated previously. The figure exemplifies the case=0.6. In this case, the voltage is 5.3 V in ordinary operation and 6.4 V in aging.

According to the present invention, as described above, the characteristics in ordinary operation of an internal supply and the characteristics thereof in testing or aging can be designed independent of each other, and a voltage converter enabling the testing or aging of a semiconductor device can be prepared.

FIG. 17 shows a fourth embodiment of the present invention. This embodiment is characterized in that level shift circuits composed of Q_(L1), Q_(L3) and Q_(L2), Q_(L4) are inserted into the input terminal of the differential amplifier of the prior-art limiter shown in FIG. 26.

In this embodiment, a prescribed voltage V_(G) is impressed on the gates of Q_(L3) and Q_(L4), and they operate as constant current sources. Accordingly, a fixed current flows to Q_(L1) and Q_(L2) irrespective of the gate voltage thereof. When the gate voltage of Q_(L1), Q_(L2) is denoted by V_(i), the source voltage thereof by V_(o), the drain current by I_(D) and the drain conductance by β, an equation of I_(D) =β/2 (V_(i) -V_(o) -V_(T))² is established, and therefore the relationship between the output voltage and the input voltage is expressed by ##EQU5## Since V_(T) and I_(D) are unvaried, V_(o) is lower by ##EQU6## than V_(i).

V_(o) =1.6(V) when V_(i) =3(V), V_(T) =1(V), I_(D) =1(μA) and β=10⁻⁵ (μS/V), and therefore the operational range of the differential amplifier is determined to be V_(CC) ≦V_(o) +V_(T) =2.6(V), as described previously.

According to the present embodiment, therefore, a voltage limiter circuit being operable sufficiently even with V_(CC) =3(V) can be realized.

In this method, signals are delayed by the provision of the level shift circuits. In order to make the device operate at higher speed, therefore, these circuits need to be deleted.

FIG. 16 shows an embodiment (fifth embodiment) which solves the above-stated problem. This embodiment is characterized in that the differential amplifier of the prior-art limiter shown in FIG. 26 is replaced by the previously-described amplifier having P-channel transistors as a load. Herein a reference voltage VL (VL₁ in the figure) is inputted to the gate of an N-channel source-coupled pair transistor Q₃. On the other side, a limiter output VLO (VLO₁ in the figure) is inputted to the gate of the other source-coupled pair transistor Q₄. Since a comparison voltage is inputted directly to the N-channel source-coupled pair in this way, the number of elements through which signals pass can be reduced, and thus a high-speed operation can be attached. Besides, the source-coupled pair is of N-channel, and therefore the gate-source voltage thereof is determined on the basis of V_(ss), and so a current is not dependent on V_(CC). In regard to VL, the operation is enabled in a wide range from V_(T) to V_(CC) when the threshold voltage of the source-coupled pair is V_(T).

By the way, a transistor Q₅ for current control of the amplifier turns to be of N-channel, and therefore the phase of a control signal φ₁, therefor turns to be reverse to φ₁ ' of FIG. 17.

FIG. 18 shows a sixth embodiment of the present invention. This embodiment is characterized in that the current control transistor of the differential amplifier is divided into a plurality of units (three in the present embodiments) and each of them is driven by a signal being different in timing from one another.

The following is a description on the operation. In the figure, mark VC3 denotes a voltage limiter circuit, MCA a memory cell array to DRAM, DD a data line, W a word line, Q_(M) and C_(S) memory cells, Q_(S1) to Q_(S4) sense amplifiers, Q_(SP) a transistor for driving the sense amplifier constituted by P-channel transistors Q_(S1), Q_(S2), and Q_(SN) a transistor for driving the sense amplifier constituted by N-channel transistors Q_(S3), Q_(S4). Mark φ_(p) denotes a precharge signal.

FIG. 19 shows operation timings of the circuit shown in FIG. 18. In the figure, data lines D, D are precharged at VL/2. When a word-line signal W rises herein, Q_(M) turns ON, and a signal stored in C_(S) appears on the data lines D, D. When sense amplifier drive signals φ_(SP), φ_(SN) are charged subsequently, the sense amplifiers operate to amplify the foregoing signal. On the occasion, Q_(S1), Q_(S2) charge a data-line capacity C_(D) on the High side up to VL, while Q_(S3), Q_(S4) discharge a data-line capacity C_(D) on the Low side down to V_(ss). A current waveform I_(D) obtained when the data lines are charged has a shape of rising sharply and falling gradually as indicated by a broken line in FIG. 19, since the voltage limiter responds to load fluctuation at high speed when φ₁, φ₂, φ₃ are made to rise simultaneously. Accordingly, the peak value of the current is large. This sharp fluctuation of the current makes a supply voltage fluctuate, which causes a false operation of the device. In the present embodiment, in contrast, φ₁, φ₂, φ₃ are made to rise at an appropriate time interval after the sense amplifiers are driven, and consequently the response speed of the amplifiers is slow at first. Therefore the drivability of the voltage limiter becomes low, the peak just after charging is thereby reduced, and thus the waveform is shaped in a trapezoid as indicated by a solid line in the figure.

On the other side, the current consumed by the amplifiers themselves is also reduced by an amount indicated by a hatched part in the figure.

As described above, the present embodiment has an effect that the peak current is reduced in charging. In addition, it enables the reduction of a power consumed by the voltage limiter itself.

By applying the voltage limiter of the present embodiment to a circuit having a plurality of loads different in capacity, besides, an optimum consumed current can be selected in accordance with the capacity of each load, and thus power reduction can be attained.

FIG. 20 shows a seventh embodiment of the present invention. This embodiment is characterized in that a plurality of voltage limiter circuits VC1 shown in FIG. 16 are connected in parallel and separate signals (φ₁, φ₂, φ₃) are used as current control signals for the circuits respectively. This construction enables the attainment of the same effect as the fifth embodiment. Since the same circuits are connected in parallel, layout is needed only for one circuit, and thus the number of processes for design can be lessened.

FIG. 21 shows a circuit which generates a current control signal for the differential amplifier. The present-embodiment is characterized in that it enables the detection of the amount of fluctuation of an output voltage of the limiter and the automatic selection of a current value corresponding in amplitude thereto.

In the figure, mark DA denotes a differential amplifier as shown in FIG. 23, and VF₁, VF₂, VF₃ reference voltages being in the relationship of VL>VF₁ >VF₂ >VF₃. Besides, the channel widths W₅₀, W₅₁, W₅₂ of current controlling transistors Q₅₀, Q₅₁, Q₅₂ are in the relationships of W₅₀ ≧W₅₁ ≧W₅₂.

The operation of this circuit will be described by using FIG. 25. When a drive signal φ is charged on a load L, a current flows through L and VL0 lowers. If VL0 lowers below VF₃, on the occasion, VF₁ and VF₂ turn to be higher than VL0 based on the above-stated relationship, therefore the plus input of all the three differential amplifiers becomes higher than the minus input thereof, and thus the state of all of φ_(A), φ_(B), φ_(C) changes from Low to High. Then all of Q₅₀, Q₅₁, Q₅₂ turn ON, the maximum current flows through a differential amplifier VC3, and thus the limiter turns to have the maximum drivability. If VL0 lowers to a voltage between VF₁ and VF₂, only φ_(C) turns High, and thereby Q₅₂ alone is turned ON. If VL0 lowers down to a voltage between VF₂ and VF₃, φ_(B) and φ_(C) turn High, and thereby Q₅₁ and Q₅₂ are turned ON.

As described above, the present embodiment enables the realization of an automatic operation wherein current controlling transistors in larger numbers are turned ON as VL0 lowers in a larger amount, while said transistors in smaller numbers are turned ON as VL0 lowers in a smaller amount, to the contrary. Accordingly, it is unnecessary to keep the current controlling transistors to be ON for a longer time than an actual charging time in view of the fluctuation in a supply voltage or the non-uniformity in processes as in the prior art, and thus a further power reduction can be attained. Moreover, it becomes unnecessary to extend wirings to the limiter for many current control signals, and therefore an area for layout can be reduced. Furthermore a circuit design is facilitated since it becomes unnecessary to know a change in a time required for a current flowing to a load.

FIG. 22 shows a circuit wherein a complementary MOS (hereinafter abbreviated as CMOS) inverter circuit INV shown in FIG. 24 is inserted into the rear stage of the differential amplifier DA shown in FIG. 21. Since the phase of an output is thereby inverted, an input to DA is inverted herein to the one of FIG. 21.

The present embodiment is characterized in that a gain of a control signal generator is increased by the inverter circuit. Thereby differences among VL, VF₁, VF₂ and VF₃ can be made small, and therefore the amount of variation of VL0 can be lessened. In addition, an output voltage of the amplifier is turned to be V_(CC) at High level and V_(ss) at LoW level by the CMOS inverter circuit. Therefore the current controlling transistors Q₅₀, Q₅₁, Q₅₂ can be turned ON and OFF completely, and thereby a still further power reduction can be attained.

While MIS LSI is taken as an example in the above description of the present invention, the same effect can be produced also for bipolar LSI or Bi-CMOS LSI wherein the above two types of LSI are integrated.

According to the fourth to seventh embodiments described above, the differential amplifier of the voltage limiter circuit can make a large current flow even when the input voltage thereof becomes equal to a supply voltage. This enables the realization of the voltage limiter circuit which operates at high speed even when the supply voltage lowers and becomes equal to the output voltage of the voltage limiter.

Besides, these embodiments enable the fine control of drivability in accordance with the state of a load, and therefore power reduction can be attained. 

We claim:
 1. A semiconductor memory comprising:a memory cell having a first MOS transistor; a data line coupled to a drain or a source of said first MOS transistor; a word line coupled to a gate of said first MOS transistor; and a voltage converter for converting an external supply voltage which is supplied from outside of said semiconductor memory, into an internal supply voltage which is supplied to said word line in said semiconductor memory;wherein said voltage converter comprises: a first circuit for supplying a first reference voltage of substantially constant magnitude irrespective of fluctuations of said external supply voltage; a second circuit for supplying a second reference voltage being dependent on magnitude of said external supply voltage, and independent from said first reference voltage; a second MOS transistor having a first source/drain terminal coupled to the external supply voltage; a first differential amplifier having an inverting input, a non-inverting input and an output, wherein the output is coupled to a gate of said second MOS transistor; a third MOS transistor having a first source/drain terminal coupled to the external supply voltage; a second differential amplifier having an inverting input, a non-inverting input and an output, wherein the output is coupled to a gate of said third MOS transistor; and an output terminal coupled to a second source/drain terminal of said second MOS transistor and a second source/drain terminal of said third MOS transistor, wherein the inverting input of said first differential amplifier is coupled to the output of said first circuit, the inverting input of said second differential amplifier is coupled to the output of said second circuit, and wherein both the non-inverting input of said first differential amplifier and the non-inverting input of said second differential amplifier are coupled to said output terminal.
 2. The semiconductor memory according to claim 1, wherein said voltage converter further comprises:a current source coupled to said output terminal of said voltage converter.
 3. The semiconductor memory according to claim 1, wherein said voltage converter further comprises:a voltage dividing means between said output terminal of said voltage converter and said non-inverting input of said first differential amplifier.
 4. The semiconductor memory according to claim 1, wherein said voltage converter further comprises:a voltage dividing means between said output terminal of said voltage converter and said non-inverting input of said second differential amplifier.
 5. The semiconductor memory according to claim 1, further comprising:a word line booster coupled between said output terminal of said voltage converter and the word line; wherein said word line booster boosts said internal supply voltage to a boosted voltage having a magnitude which is a predetermined amount larger than the magnitude of said internal supply voltage.
 6. A semiconductor memory according to claim 4, wherein said semiconductor memory is a random access memory.
 7. A semiconductor memory according to claim 6, wherein said semiconductor memory is a dynamic random access memory.
 8. A semiconductor memory according to claim 5, wherein said semiconductor memory is a random access memory.
 9. A semiconductor memory according to claim 8, wherein said semiconductor memory is a dynamic random access memory. 